Chemical vapor deposition reactor having multiple inlets

ABSTRACT

A chemical vapor deposition reactor has a wafer carrier which cooperates with a chamber of the reactor to facilitate laminar flow of reaction gas within the chamber and a plurality of injectors configured in flow controllable zones so as to mitigate depletion.

RELATED APPLICATION

This patent application is a continuation of co-pending patentapplication Ser. No. 11/932,293, filed Oct. 31, 2007, which is acontinuation of patent application Ser. No. 11/064,984, filed Feb. 23,2005, which is a continuation-in-part (CIP) patent application of nowabandoned patent application Ser. No. 10/621,049, filed Jul. 15, 2003and entitled CHEMICAL VAPOR DEPOSITION REACTOR, the entire contents ofwhich are hereby incorporated explicitly by reference.

FIELD OF THE INVENTION

The present invention relates generally to chemical vapor deposition(CVD) reactors, such as those used for group III-V semiconductorepitaxy. The present invention relates more particularly to a CVDreactor that is configured to provide laminar flow of reactant gaseswhile mitigating undesirable depletion of reactants, so as to achieveenhanced deposition uniformity.

BACKGROUND OF THE INVENTION

Metal organic chemical vapor deposition (MOCVD) of group III-V compoundsis a thin film deposition process utilizing a chemical reaction betweena periodic table group III organic metal and a periodic table group Vhydride. Various combinations of group III organic metal and group Vhydride are possible.

This process is commonly used in the fabrication of semiconductordevices, such as light emitting diodes (LEDs). The process usually takesplace in a chemical vapor deposition (CVD) reactor. CVD reactor designis a critical factor in achieving the high quality films that arerequired for semiconductor fabrication.

In general, the gas flow dynamics for high quality film deposition favorlaminar flow. Laminar flow, as oppose to convective flow, is required toachieve high growth efficiency and uniformity. Several reactor designsare commercially available to provide laminar growth condition on alarge scale, i.e., high throughput. These designs include the rotatingdisk reactor (RDR), the planetary rotating reactor (PRR) and theclose-coupled showerhead (CCS).

However, such contemporary reactors suffer from inherent deficiencieswhich detract from their overall desirability, particularly with respectto high pressure and/or high temperature CVD processes. Suchcontemporary reactors generally work well at low pressures andrelatively low temperatures (such as 30 torr and 700° C., for example).Therefore, they are generally suitable for growing GaAs, InP basedcompounds.

However, when growing group III nitride based compounds (such as GaN,AlN, InN, AlGaN, and InGaN), there are factors that become importantwhen using such contemporary reactors. Unlike GaAs or InP basedmaterial, group III Nitride is preferably grown at substantially higherpressures and temperatures (generally greater that 500 torr and greaterthan 1000° C.). When using the aforementioned reactor designs under highpressure and temperature conditions, heavy thermal convection inherentlyoccurs. Such thermal convection undesirably interferes with the growthprocess, so as to degrade efficiency and yield.

This situation worsens when the gas phase is majority ammonia. Ammoniais commonly used as nitrogen source in the III nitride MOCVD process.Ammonia is much more viscous than hydrogen. When the ambient gascontains a high percentage of ammonia, thermal convection occurs moreeasily than when the ambient gas is majority hydrogen, which is the casefor GaAs or InP based MOCVD growth. Thermal convection is detrimental togrowing high quality thin films since hard-to-control complex chemicalreactions occur due to the extended duration of the presence of reactantgases in the growth chamber. This inherently results in a decrease ingrowth efficiency and poor film uniformity.

According to contemporary practice, a large gas flow rate is typicallyutilized in order to suppress undesirable thermal convection. In thegrowth of group III nitride, this is done by increasing the ambient gasflow rate, wherein the gas is typically a mixture of ammonia with eitherhydrogen or nitrogen. Therefore, high consumption of ammonia results,particularly at high growth pressure conditions. This high consumptionof ammonia results in the corresponding high costs.

Reaction between source chemicals in the gas phase is another importantissue in the contemporary MOCVD process for growth of GaN. This reactionalso occurs in the growth of other group III-Nitrides, such as AlGaN andInGaN. Gas phase reaction is usually not desirable. However, it is notavoidable in the group III nitride MOCVD process because the reaction issevere and fast.

When the group III alkyls (such as trimethylgallium, trimethylindium,trimethylaluminum) encounter ammonia, a reaction occurs almostimmediately, resulting in the undesirable formation of adducts

Usually, when these reactions occur after all the source gases enter thegrowth chamber, the adducts produced will participate in the actuallygrowth process. However, if the reactions happen before or near the gasentrance of the growth chamber, the adducts produced will have anopportunity to adhere to the solid surface. If this happens, the adductswhich adhere to the surface will act as gathering centers and more andmore adduct will consequently tend to accumulate. This process willeventually deplete the sources, thereby making the growth processundesirably vary between runs and/or will clog the gas entrance.

An efficient reactor design for III-nitride growth does not avoid gasphase reaction, but rather controls the reaction so that it does notcreate such undesirable situations.

Because the demand for GaN based blue and green LEDs have increaseddramatically in recent years, throughput requirements from productionreactors has become important. The contemporary approach to scale upproduction is typically to build larger reactors. The number of wafersproduced during each run has increased from 6 wafers to more than 20wafers, while maintaining same number of runs per day, in currentlyavailable commercial reactors.

However, when a reactor is scaled up this way, several new issues arise.Because thermal convection is as severe (or even more sever) in a largerreactor as in a smaller reactor, film uniformity, as well aswafer-to-wafer uniformity, are not any better (and may be much worse).Further, at higher growth pressures, a very high gas flow rate is neededto suppress thermal convection. The amount of gas flow needed is so highthat modification and special considerations are required for the gasdelivery system.

Additionally, because of the high temperature requirements, the largermechanical parts of such a scaled up (larger) reactor are inherentlyplaced under higher thermal stress and consequently tend to breakprematurely. In almost all reactor constructions, stainless steel,graphite and quartz are the most commonly used materials. Because ofhydrogenation of the metals utilized (making them become brittle) andbecause of etching of graphite by ammonia at high temperatures, thelarger metal and graphite parts tend to break down much sooner than thecorresponding parts of smaller reactors. Larger quartz parts also becomemore susceptible to breakage because higher thermal stress.

Another issue associated with large size reactors is the difficulty inmaintaining high temperature uniformity. Thickness and compositionuniformity can be immediately affected by the temperature uniformity ofthe wafer carrier surface. In large size reactors, temperatureuniformity is achieved by using a multi-zone heating configuration thatis complex in design. The reliability of the heater assembly is usuallypoor due to the aforementioned high thermal stress and ammoniadegradation. These issues of process inconsistency and extensivehardware maintenance have a significant impact on production yield andtherefore product cost.

Referring now to FIG. 1, an example of a contemporary RDR reactor foruse in GaN epitaxy is shown schematically. The reaction chamber has adouble-walled water-cooled 10″ cylinder 11, a flow flange 12 where allthe reaction or source gases are distributed and delivered into chamber13, a rotation assembly 14 that spins the wafer carrier 16 at severalhundreds of rotations per minute, a heater 17 assembly underneath thespinning wafer carrier 16 configured to heat wafers 10 to desiredprocess temperatures, a pass through 18 to facilitate wafer carriertransfer in and out of the chamber 13, and an exhaust 19 at the centerof the bottom side of the chamber 13. An externally driven spindle 21effects rotation of the wafer carrier 16. The wafer carrier 16 comprisesa plurality of pockets, each of which is configured to contain a wafer10.

The heater 17 comprises two sets of heating elements. An inner set ofheating elements 41 heats the central portion of the wafer carrier 16and an outer set of heating elements 42 heats the periphery of the wafercarrier 16. Because the heater 17 is inside of the chamber 13, it isexposed to the detrimental effects of the reaction gases.

The spindle rotates the wafer carrier at between 500 and 1000 rpm.

As discussed previously, this design works well at lower pressures andtemperatures, especially when the ambient gas is low viscosity. However,when growing GaN at high pressures and temperatures in a high ammoniaambient gas, then thermal convection occurs and gas flow tends to beundesirably turbulent.

Referring now to FIG. 2, a simplified gas streamline is shown toillustrate this turbulence. It is clear that turbulence increase as thesize of the chamber and/or the distance between the wafer carrier andthe top of the chamber increases. When the design of FIG. 1 is scaled upfor higher throughput, the chamber 13, as well as the wafer carrier 16,is enlarged to support and contain more wafers.

Gas recirculation cells 50 tend to form when there is turbulence in theambient gas. As those skilled in the art will appreciate, suchrecirculation is undesirable because it results in undesirablevariations in reactant concentration and temperature. Further, suchrecirculation generally results in reduced growth efficiency due toineffective use of the reactant gas.

Further, more heating zones are required in a larger reactor. This, ofcourse, undesirably complicates the construction of such larger reactorsand increases the cost thereof.

Referring now to FIGS. 3A and 3B, a comparison between a 7″ six pocketwafer carrier 16 a (which supports six wafers as shown in FIG. 3A) and a12″ twenty pocket wafer carrier 16 b (which supports twenty wafers asshown in FIG. 3 b) can easily be made. Each pocket 22 supports a single2″ round wafer. From this comparison, it is clear that such scaling upof a reactor to accommodate more wafers greatly increases the size,particularly the volume, thereof. This increase in the size of thereactor results in the undesirable effects of thermal convection and theadditional complexities of construction discussed above.

It is well known, however, that the depletion effect is one majordrawback in contemporary horizontal reactors. As reactants in thecarrier gas proceed from the center toward the peripheral of therotating disk, a substantial amount of the reactants is consumed alongthe way. This undesirably makes the thin film deposited thinner andthinner along the radial direction upon the wafer.

One contemporary approach to reduce the depletion effect is to use ahigh gas flow rate to reduce the concentration gradient along the radialdirection. The drawback of this approach is an inherent decrease ingrowth efficiency.

In view of the foregoing, it is desirable to provide a reactor which isnot substantially susceptible to the undesirable effects of thermalconvection and which can easily and economically be scaled up so as toincrease throughput. It is further desirable to provide a reactor whichhas enhanced growth efficiency (such as by providing mixing of reactantgases immediately proximate a growth region of the wafers and byassuring intimate contact of the reactant gases with the growth region).It is yet further desirable to provide a reactor wherein the heater isoutside of the chamber thereof, and is thus not exposed to thedetrimental effects of the reaction gases. It is yet further desirableto mitigate the undesirable effects of depletion while maintaininggrowth efficiency, so as to provide enhanced deposition uniformity overthe entire wafer.

BRIEF SUMMARY OF THE INVENTION

While the apparatus and method has or will be described for the sake ofgrammatical fluidity with functional explanations, it is to be expresslyunderstood that the claims, unless expressly formulated under 35 USC112, are not to be construed as necessarily limited in any way by theconstruction of “means” or “steps” limitations, but are to be accordedthe full scope of the meaning and equivalents of the definition providedby the claims under the judicial doctrine of equivalents, and in thecase where the claims are expressly formulated under 35 USC 112 are tobe accorded full statutory equivalents under 35 USC 112.

The present invention specifically addresses and alleviates the abovementioned deficiencies associated with the prior art. More particularly,according to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier whichcooperates with a chamber of the reactor to facilitate laminar flow ofreaction gas within the chamber.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier which issealed at a periphery thereof to a chamber of the reactor such thatlaminar flow within the chamber is facilitated.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber and a rotatable wafercarrier disposed within the chamber, the wafer carrier being configuredso as to enhance outward flow of reaction gas within the chamber.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier and areaction chamber, a bottom of the reaction chamber being substantiallydefined by the wafer carrier.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber, a wafer carrier disposedwithin the chamber, and a heater disposed outside of the chamber, theheater being configured to heat the wafer carrier.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a plurality of chambers and at leastone of a common reactant gas supply system and a common gas exhaustsystem.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a wafer carrier configured such thatreactant gas does not flow substantially below the wafer carrier.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber, a wafer carrier, a gasinlet located generally centrally within the chamber, and at least onegas outlet formed in the chamber entirely above an upper surface of thewafer carrier so as to enhance laminar gas flow through the chamber.

According to another aspect, the present invention comprises a chemicalvapor deposition reactor comprising a plurality of injectors configuredso as to mitigate depletion. More particularly, a chemical vapordeposition reactor comprises a wafer carrier which cooperates with achamber of the reactor to facilitate laminar flow of reaction gas withinthe chamber and also comprises a plurality of injectors configured so asto mitigate depletion.

The chemical vapor deposition reactor can comprise an inlet disposedproximate a central portion thereof. The injectors can comprise groupIII injectors. The inlet can comprise a group V inlet.

The injectors can define a plurality of zones and each zone can have adedicated flow controller. For example, the injectors can define threezones, the injectors of each zone having a dedicated flow controller.

The flow through each zone can be individually controllable.Additionally, the flow through each injector can optionally beindividually controllable. Further, the reactant concentration througheach zone can be individually controllable. Additionally, the reactantconcentration through each injector can optionally be individuallycontrollable.

According to another aspect, the present invention comprises a methodfor chemical vapor deposition comprising injecting reactant gas into areactor chamber in a manner that mitigates depletion. More particularly,the method can comprise rotating a wafer carrier within a chamber of areactor, the wafer carrier cooperating with the chamber to facilitatelaminar flow of reaction gas within the chamber; and injecting a gasreactant into the chamber via plurality of injectors configured so as tomitigate depletion.

Gas, such as a group V reactant, e.g., NH₃, can be added to the chambervia an inlet disposed proximate a central portion thereof. The gasinjected into the chamber via the injectors can comprise group IIIreactants.

The gas flow through groups of controllers (such as corresponding to thezones) can be controlled. The flow can be controlled based upon whichone of a plurality of zones the injectors are located within.

Thus, according to one aspect, the present invention comprises a lid fora chemical vapor deposition reactor, wherein the lid comprises or isconfigured to comprise a plurality of injectors.

These, as well as other advantages of the present invention, will bemore apparent from the following description and drawings. It isunderstood that changes in the specific structure shown and describedmay be made within the scope of the claims, without departing from thespirit of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention and its various embodiments can now be better understoodby turning to the following detailed description of the preferredembodiments which are presented as illustrated examples of the inventiondefined in the claims. It is expressly understood that the invention asdefined by the claims may be broader than the illustrated embodimentsdescribed below.

FIG. 1 is a semi-schematic cross-sectional side view of a contemporaryreactor showing reaction gas being introduced thereinto in a dispersedfashion via a flow flange and showing the gas being exhausted from thechamber via a gas outlet disposed below the wafer carrier;

FIG. 2 is a semi-schematic cross-sectional side view of a contemporaryreactor showing undesirable convection caused re-circulation of reactiongas within the chamber, wherein the re-circulation is facilitated by thecomparatively large distance between the top of the chamber and thewafer carrier;

FIG. 3A is a semi-schematic top view of a wafer carrier which isconfigured so as to support six wafers within a reactor;

FIG. 3B is a semi-schematic top view of a wafer carrier which isconfigured so as to support twenty wafers within a reactor;

FIG. 4 is a semi-schematic cross-sectional side view of a reactor havinga comparatively small distance between the top of the chamber and thewafer carrier and having a single comparatively small gas inlet disposedgenerally centrally with respect to the wafer carrier according to thepresent invention;

FIG. 5 is a semi-schematic cross-sectional side view of an alternativeconfiguration of the reactor of FIG. 4, having a plurality of reactiongas outlets disposed entirely above the upper surface of the wafercarrier and in fluid communication with a ring diffuser so as to enhancelaminar gas flow, having a seal disposed between the wafer carrier andthe chamber, and having a heater disposed outside of the chamber alongwith a heater gas purge so as to mitigate the effects of reactant gasupon the heater, according to the present invention;

FIG. 6A is a semi-schematic cross-sectional top view of the reactor ofFIG. 5, showing a three pocket wafer carrier, the seal between the wafercarrier and the chamber, the diffuser, and the reaction gas outlets;

FIG. 6B is a semi-schematic perspective side view of the diffuser ofFIGS. 5 and 6A showing a plurality of apertures formed in the innersurface and the outer surface thereof;

FIG. 7 is a semi-schematic cross-sectional side view of an alternativeconfiguration of the reactor of FIG. 5, having a separate alkyl inletand a separate ammonia inlet providing reaction gas to a carrier gas;

FIG. 8 is a semi-schematic cross-sectional side view of an alternativeconfiguration of the reactor of FIG. 5, having an ammonia inlet disposedgenerally concentrically within an allyl/carrier gas inlet;

FIG. 9 is a semi-schematic perspective side view of a comparativelylarge, scaled up RDR reactor having a twenty-one wafer capacity andhaving a plurality of reaction gas inlets;

FIG. 10 is a semi-schematic perspective side view of a reactor systemhaving three comparatively small reactors (each of which has a sevenwafer capacity such that the total capacity is equal to that of thecomparative large reactor of FIG. 9) which share a common reaction gassupply system and a common reaction gas exhaust system.

FIG. 11 is a semi-schematic, cross-sectional side view of a reactorhaving a plurality of gas inlets formed so as to define a plurality ofzones; and

FIG. 12 is a semi-schematic top view of the lid of the reactor of FIG.11, better showing how the plurality of gas inlets define a plurality ofzones.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Many alterations and modifications may be made by those having ordinaryskill in the art without departing from the spirit and scope of theinvention. Therefore, it must be understood that the illustratedembodiment has been set forth only for the purposes of example and thatit should not be taken as limiting the invention as defined by thefollowing claims. For example, notwithstanding the fact that theelements of a claim are set forth below in a certain combination, itmust be expressly understood that the invention includes othercombinations of fewer, more or different elements, which are disclosedin above even when not initially claimed in such combinations.

The words used in this specification to describe the invention and itsvarious embodiments are to be understood not only in the sense of theircommonly defined meanings, but to include by special definition in thisspecification structure, material or acts beyond the scope of thecommonly defined meanings. Thus if an element can be understood in thecontext of this specification as including more than one meaning, thenits use in a claim must be understood as being generic to all possiblemeanings supported by the specification and by the word itself.

The definitions of the words or elements of the following claims are,therefore, defined in this specification to include not only thecombination of elements which are literally set forth, but allequivalent structure, material or acts for performing substantially thesame function in substantially the same way to obtain substantially thesame result. In this sense it is therefore contemplated that anequivalent substitution of two or more elements may be made for any oneof the elements in the claims below or that a single element may besubstituted for two or more elements in a claim. Although elements maybe described above as acting in certain combinations and even initiallyclaimed as such, it is to be expressly understood that one or moreelements from a claimed combination can in some cases be excised fromthe combination and that the claimed combination may be directed to asubcombination or variation of a subcombination.

Insubstantial changes from the claimed subject matter as viewed by aperson with ordinary skill in the art, now known or later devised, areexpressly contemplated as being equivalently within the scope of theclaims. Therefore, obvious substitutions now or later known to one withordinary skill in the art are defined to be within the scope of thedefined elements.

The claims are thus to be understood to include what is specificallyillustrated and described above, what is conceptionally equivalent, whatcan be obviously substituted and also what essentially incorporates theessential idea of the invention.

Thus, the detailed description set forth below in connection with theappended drawings is intended as a description of the presentlypreferred embodiment(s) of the invention and is not intended torepresent the only form(s) in which the present invention may beconstructed or utilized. The description sets forth the functions andthe sequence of steps for constructing and operating the invention inconnection with the illustrated embodiment(s). It is to be understood,however, that the same or equivalent functions may be accomplished bydifferent embodiments that are also intended to be encompassed withinthe spirit of the invention.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier whichcooperates with a chamber of the reactor to facilitate laminar flow ofreaction gas within the chamber.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier which issealed at a periphery thereof to a chamber of the reactor such thatlaminar flow within the chamber is facilitated.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber and a rotatable wafercarrier disposed within the chamber, the wafer carrier being configuredso as to enhance outward flow of reaction gas within the chamber.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a rotatable wafer carrier and areaction chamber, a bottom of the reaction chamber being substantiallydefined by the wafer carrier.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber, a wafer carrier disposedwithin the chamber, and a heater disposed outside of the chamber, theheater being configured to heat the wafer carrier.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a plurality of chambers and at leastone of a common reactant gas supply system and a common gas exhaustsystem.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a wafer carrier configured such thatreactant gas does not flow substantially below the wafer carrier.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber, a wafer carrier, a gasinlet located generally centrally within the chamber, and at least onegas outlet formed in the chamber entirely above an upper surface of thewafer carrier so as to enhance laminar gas flow through the chamber.

According to one aspect, the present invention comprises a chemicalvapor deposition reactor comprising a chamber, a wafer carrier disposedwithin the chamber and cooperating with a portion (for example, the top)of the chamber to define a flow channel, and a shaft for rotating thewafer carrier. A distance between the wafer carrier and the portion ofthe chamber is small enough to effect generally laminar flow of gasthrough the flow channel.

Preferably, the distance between the wafer carrier and the portion ofthe chamber is small enough for centrifugal force caused by rotation ofthe wafer carrier to effect outward movement of gas within the channel.Preferably, the distance between the wafer carrier and the portion ofthe chamber is small enough that a substantial portion of the reactantsin the reaction gas contact a surface of a wafer prior to exiting thechamber. Preferably, the distance between the wafer carrier and theportion of the chamber is small enough that most of the reactants in thereaction gas contact a surface of a wafer prior to exiting the chamber.Preferably, the distance between the wafer carrier and the portion ofthe chamber is small enough to mitigate thermal convection intermediatethe chamber and the wafer carrier.

Preferably, the distance between the wafer carrier and the portion ofthe chamber is less than approximately 2 inches. Preferably, thedistance between the wafer carrier and the portion of the chamber isbetween approximately 0.5 inch and approximately 1.5 inches. Preferably,the distance between the wafer carrier and the portion of the chamber isapproximately 0.75 inch.

Preferably, a gas inlet formed above the wafer carrier and generallycentrally with respect thereto.

Preferably, the chamber is defined by a cylinder. Preferably, thechamber is defined by a cylinder having one generally flat wall thereofdefining a top of the chamber and the reaction gas inlet in located atapproximately a center of the top of the chamber. However, those skilledin the art will appreciate that the chamber may alternatively be definedby any other desired geometric shape. For example, the chamber mayalternatively be defined by a cube, a box, a sphere, or an ellipsoid.

Preferably, the chemical vapor the wafer carrier is configured to rotateabout an axis thereof and the reaction gas inlet is disposed generallycoaxially with respect to the axis of the wafer carrier.

Preferably, the reaction gas inlet has a diameter which is less that ⅕of a diameter of the chamber. Preferably, the reaction gas inlet has adiameter which is less than approximately 2 inches. Preferably, thereaction gas inlet has a diameter which is between approximately 0.25inch and approximately 1.5 inch.

Thus, the reaction gas inlet is sized so as to cause reaction gas toflow generally from a center of the wafer carrier to a periphery thereofin a manner that results in substantially laminar reaction gas flow. Inthis manner convection currents are mitigated and reaction efficiency isenhanced.

Preferably, the reaction gas is constrained to flow generallyhorizontally within the chamber. Preferably, the reaction gas isconstrained to flow generally horizontally through the channel.Preferably, the reaction gas is caused to flow outwardly at leastpartially by a rotating wafer carrier.

Preferably, the at least one reaction gas outlet formed in the chamberabove a wafer carrier. Preferably, a plurality of reaction gas outletsis formed in the chamber entirely above the upper surface of the wafercarrier. Increasing the number of reaction gas outlet(s) enhanceslaminar flow of the reaction gas, particularly at the periphery of thewafer carrier, by facilitating radial flow of the reaction gas (byproviding more straight line paths for gas flow from the center of thewafer carrier to the periphery thereof). Forming the reaction gasoutlets entirely above the upper surface of the wafer carrier mitigatesundesirable turbulence in the reaction gas flow resulting from thereaction gas flowing over an edge of the wafer carrier.

Thus, at least one reaction gas outlet is preferably formed in thechamber above a wafer carrier and below a top of the chamber.

The chemical vapor deposition reactor preferably comprises a reactiongas inlet formed generally centrally within the chamber and at least onereaction gas outlet formed in the chamber. The wafer carrier is disposedwithin the chamber below the gas outlet(s) so as to define a flowchannel intermediate a top of the chamber and the wafer carrier suchthat reaction gas flows into the chamber through the reaction gas inlet,through the chamber via the flow channel, and out of the chamber via thereaction gas outlet.

A ring diffuser is preferably disposed proximate a periphery of thewafer carrier and configured so as to enhance laminar flow from thereaction gas inlet to the reaction gas outlet. The wafer carrier isdisposed within the chamber below the gas outlets so as to define a flowchannel intermediate a top of the chamber and the wafer carrier suchthat reaction gas flows into the chamber through the reaction gas inlet,through the chamber via the flow channel, and out of the chamber via thereaction gas outlet.

The ring diffuser preferably comprises a substantially hollow annulushaving an inner surface and an outer surface, a plurality of openingsformed in the inner surface, and a plurality of openings form in theouter surface. The openings in the inner surface enhance uniformity ofreaction gas flow over the wafer carrier.

The openings in the inner surface are preferably configured so as tocreate enough restriction to reaction gas flow therethrough so as toenhance a uniformity of reaction gas flow over the wafer carrier.

The ring diffuser is preferably comprised of a material which isresistant to deterioration caused by heated ammonia. For example, thering diffuser may be formed of SiC coated graphite, SiC, quartz, ormolybdenum.

According to one aspect of the present invention, a ring seal isdisposed intermediate the wafer carrier and the chamber. The ring sealis configured to mitigate reaction gas flow out of the chamber otherthan from the reaction gas outlet. The ring seal preferably compriseseither graphite, quartz, or SiC.

According to one aspect of the present invention, a heater assembly isdisposed outside of the chamber and proximate the wafer carrier. Theheater may be an induction heater, a radiant heater, or any otherdesired type of heater. Preferably, a heater purge system is configuredto mitigate contact of reaction gas with the heater.

Typically, a gas flow controller is configured to control the amount ofreactant gases introduced into the chamber via the gas inlet port.

The wafer carrier is preferably configured to support at least three 2inch round wafers. However, the wafer carrier may alternatively beconfigured so as to support any desired number of wafers, any desiredsize of wafers, and any desired shape of wafers.

According to one aspect of the present invention, the wafer carrier isconfigured so as to facilitate outward flow of reaction gas due tocentrifugal force. Thus, the wafer carrier preferably comprises arotating wafer carrier. The wafer carrier is preferably configured torotate at greater than approximately 500 rpm. The wafer carrier isconfigured to rotate at between approximately 100 rpm and approximately1500 rpm. The wafer carrier is preferably configured to rotate atapproximately 800 rpm.

The apparatus and method of the present invention may be used to formwafers, from which a variety of different semiconductor devices may beformed. For example, the wafers may be used to form die from which LEDsare fabricated.

The present invention is illustrated in FIGS. 1-10, which depictpresently preferred embodiments thereof. The present invention relatesto a chemical vapor deposition (CVD) reactor and an integratedmulti-reactor system which is suitable for scaled up throughput. Thereactor employs a geometry that substantially suppresses thermalconvection, a gas injection scheme providing very high gas velocity toavoid adduct adhesion to surface, and a restricted growth zone toenhance growth efficiency (by reducing source gas consumption).

For high throughput configurations, multiple units of said reactor canbe integrated. Each reactor in the multiple-unit configuration can be ofa relatively small scale in size, so that the mechanical constructioncan be simple and reliable. All reactors share common gas delivery,exhaust and control systems so that cost is similar to the largerconventional reactor with the same throughput.

The throughput scaling up concept is independent with respect to reactordesign and can also be applied to various other reactor designs. Intheory, there is no limit in how many reactors can be integrated in onesystem. But as a practical matter, the maximum number of reactorsintegrated is substantially limited by how the gas delivery system isconfigured. Both reactor design and the scaling up concept can also beapplied to the growth of various different materials, and thus includesbut is not limited to group III-nitride, all other group III-Vcompounds, oxides, nitrides, and group V epitaxy.

Referring now to FIG. 4, a reactor 100 has a narrow gas inlet 112located at the top and center of the reactor cylinder 111. The cylinder111 is double walled and water cooled, like the reactor shown in FIG. 1.The temperature of the water can be varied so as to control thetemperature of the chamber 113. A narrow gas channel 130 defined by thewafer carrier 116 and the top 131 of the reactor 100 directs gasoutwardly.

Pockets formed in the wafer carrier 116 are configured to receive andsupport wafers 110, such as 2 inch wafers suitable for use in thefabrication of LEDs.

The rotating wafer carrier 116 assists gas flow outwardly by itscentrifugal force. The rotating wafer carrier 116 preferably rotates atbetween 10 and 1500 rpm. As those skilled in the art will appreciate,higher rotational speeds of the wafer carrier 116 typically result ingreater centrifugal force being applied to the reaction gas.

By introducing the gas from the center, the gas is forced to flowgenerally horizontally in the narrow channel 130, making the growthprocess somewhat simulate a horizontal reactor. As those skilled in theart will appreciate, one advantage of a horizontal reactor is its highergrowth efficiency. This is because all the reactants in a horizontalreactor are restricted to a much narrower volume, thus making thereactants more efficient in their contact with the growing surface.

Preferably, the reaction gas inlet has a diameter, dimension A, which isless that ⅕ of a diameter of the chamber. Preferably, the reaction gasinlet has a diameter which is less than approximately 2 inches.Preferably, the reaction gas inlet has a diameter which is betweenapproximately 0.25 inch and approximately 1.5 inch.

Unlike the use of additional gas flow to suppress thermal convection inthe vertical type of reactor such as the RDR as shown in FIG. 2, thesuppression of thermal convection is accomplished by using the narrowflow channel 130, so that gas flow is forced in the desired direction.

The distance between the upper surface of the wafer carrier 116 and thetop of the chamber 111 is designated as dimension B. Dimension B ispreferably less than approximately 2 inch. Dimension B is preferablybetween approximately 0.5 inch and approximately 1.5 inch. Dimension Bis preferably approximately 0.75 inch.

As discussed above, the depletion effect is one major drawback inhorizontal reactors. As reactants in the carrier gas proceed from thecenter toward the peripheral of the rotating disk, a substantial amountof the reactants is consumed along the way, making the thin filmdeposited thinner and thinner along the radial direction upon the wafer.

According to the present invention, growth efficiency is improved byusing a comparatively high wafer carrier rotation rate, so that thecentrifugal force generated by the rotation of the wafer carrierenhances the gas speed over the wafers without using higher gas flowrate.

Referring now to FIG. 5, gas flow resistance can be reduced, so that ahigher degree of laminar flow is produced, by forming the reaction gasoutlet(s) such that they are entirely above the upper surface of thewafer carrier. By forming the gas outlet entirely above the uppersurface of the wafer carrier 116, a more direct route (and thus lesscontorted) for the reaction gas from the gas inlet 112 to the gas outlet119 is provided. As those skilled in the art will appreciate, the moredirect and the less contorted the route of the reaction gas, the lessturbulent (and more laminar) its flow will be.

By adding a ring seal 132 around the rotating wafer carrier 116 tobridge the flow channel 130 of the exhaust gas flow, flow resistance isreduced and laminar flow substantially enhanced. This is because achange of gas flow direction at the wafer carrier's edge is eliminated.The ring seal 132 can be made of quartz, graphite, SiC or other durablematerials for suitable for the reactor's environment.

In order to achieve even pumping of exhaust gas (and thus more laminarflow), a ring shaped diffuser 133 (better shown in FIGS. 6A and 6B) canbe used. The ring shaped diffuser 133 effectively makes almost theentire periphery of the reactor, proximate the periphery of the wafercarrier 132, one generally continuous gas outlet port.

A heater 117 is disposed outside of the chamber (which is that portionof the reactor within which reaction gas readily flows). The heater isdisposed beneath the wafer carrier 116. Since the ring seal 132mitigates reaction gas flow beneath the wafer carrier 116, the heater isnot substantially exposed to reaction gas and thus is not substantiallydegraded thereby.

Preferably, a heater purge 146 is provided so as to purge any reactiongas that leaks past the ring seal 132 into the area beneath the wafercarrier.

Referring now to FIG. 6A, four pumping ports or gas outlets 119 are influid communication with the diffuser 133. All of the gas outlets 119are preferably connected to a common pump.

The ring seal 132 bridges the gap between the wafer carrier 116 and thechamber 111, so as to facilitate laminar flow of reaction gas, asdiscussed above.

Referring now to FIG. 6B, the diffuser 133 comprises a plurality ofinner apertures 136 and a plurality of outer apertures 137. As thoseskilled in the art will appreciate, the greater the number of innerapertures 136 that there are, the more nearly the inner aperturesapproximate a single continuous opening. Of course, the more nearly theinner apertures approximate a single continuous opening, the morelaminar the gas flow through the chamber.

The diffuser 133 preferably comprises at least as many outer aperturesas there are gas outlet ports (there are, for example, four gas outletports 119 shown in FIG. 5A).

The diffuser 133 is preferably made of graphite, SiC coated graphite,solid SiC, quartz, molybdenum, or other material that resist hotammonia. Those skilled in the art will appreciate that various materialsare suitable.

The size of the holes in the diffuser 133 can be made small enough tocreate slight restriction to the gas flow so that more even distributionto the exhaust can be achieve. However, the hole size should not be madeso small that clogging is likely to occur, since reaction productcontains vapor and solid particulate that may adhere to or condense uponthe diffuser holes.

Referring now to FIGS. 7 and 8, the reactant gas injection configurationcan be modified to improve gas phase reaction. According to thesemodified configurations, alkyls and ammonia are mostly separated beforebeing introduced into the reaction chamber as shown in FIG. 7, and arecompletely separated before entering the reaction chamber as shown inFIG. 8. In both cases, the reactants are mixed immediately beforereaching the growth zone where wafers are located. Gas phase reactiononly happens in a very short time before gases participate in the growthprocess.

With particular reference to FIG. 7, an alkyl inlet 141 is separate froman ammonia inlet 142. Both the alkyl inlet 141 and the ammonia inlet 142provide a reaction gas to the carrier gas inlet 112 immediately prior tothese gases entering the chamber 111.

With particular reference to FIG. 8, the alkyl inlet 141 provides areaction gas to the carrier inlet 112 much the same as in FIG. 7. Theammonia inlet 151 comprises a tube disposed within the carrier inlet112. The ammonia inlet is preferably disposed generally concentricallywithin the carrier inlet 112. However, those skilled in the art willappreciate that various other configurations of the alkyl inlet 141, theammonia inlet 151, and the carrier inlet 112 are likewise suitable.

A nozzle 161 tends to spread ammonia evenly across the wafer carrier 116so as to provide enhance reaction efficiency.

The reaction gas inlet configurations of both FIG. 7 and FIG. 8 mitigateundesirable gas phase reactions prior to the reaction gases contactingthe wafers.

As mentioned above, an advantage of the reactor configuration shown inFIGS. 5, 7, and 8 is the significant reduction of undesirable depositsupon the heater 117. The heater assembly can be either a radiant heateror a radio frequency (RF) inductive heater. By providing a heater purge146 to the lower part of the reactor 111, reaction gas can beeffectively prevented from entering the heater region. Thus, anyreaction gas leaks past the ring seal 132 is quickly purged from theheater region, such that deterioration of the heater 117 caused therebyis mitigated.

According to one aspect, the present invention comprises a way to scaleup the throughput of a metal organic chemical vapor deposition (MOCVD)system or the like. Unlike contemporary attempts to scale up a MOCVDreactor by increasing the size of the reaction chamber, presentinvention integrates several smaller reactor modules to achieve the samewafer throughput.

Referring now to FIG. 9, a twenty-one wafer reactor 900 is shown.Because of the large size of the reactor 900, gas is usually introducedthrough multiple ports 901-903 so as to provide even distributionthereof. Gas flow controllers 902 facilitate control of the amount ofreaction gas and the amounts of the components of the reaction gasprovided to the chambers.

A gas supply system 940 provides reaction gas to the ports 901-903. Agas exhaust system 950 removes the spent reaction gas from the reactor11.

Referring now to FIG. 10, an integrated three chamber reactor of thepresent invention is shown. Each chamber 951-953 is a comparativelysmall chamber, each defining, for example, a seven wafer reactor. All ofthe reactors share the same gas inlet system 960 and gas exhaust system970.

Both the configuration of FIG. 9 and the configuration of FIG. 10 yieldthe same twenty-one wafer throughput. However, there are substantialadvantages of the present invention, as shown in FIG. 10, as compared tothe reactor as shown in FIG. 9. Smaller reactors have better hardwarereliability, especially for group III nitride growth, since smallermechanical parts have lower thermal stress at high temperatures.

Further, growth consistency is better achieved with smaller reactors,since temperature and flow dynamics are much easier to maintain than inlarger reactors. Also, since construction of smaller reactor is muchsimpler than larger reactor, maintenance of smaller reactor is mucheasier and takes less time. Therefore, a smaller reactor usually hashigher uptime, as well as less frequent and less expensive partsservice.

All of these factors result in much lower cost of ownership for smallreactors, since real wafer yield is higher and maintenance cost islower. Since the cost to build a reactor is only about 2-5% of a wholeMOCVD system, adding multiple reactors in the system does not increaseoverall cost appreciably. The benefit of this invention is much greaterthan the cost of additional reactors.

As discussed in detail above, the present invention comprises a chemicalvapor deposition reaction chamber having a rotatable wafer carrier, anarrow flow channel, a gas inlet located at he center of the top lid, agas exit above the wafer carrier, a sealing ring around the wafercarrier to facilitate flow laminarly to the exhaust and to define aheater chamber.

During the growth process (deposition), the wafer carrier is rotating,typically at hundreds of rpm, e.g., 500-1500 rpm, so as to facilitatefaster gas flow in the flow channel via the use of centrifugal force.Reactants mixed with less reactive gases, such as nitrogen or hydrogen(carrier gases), are carried into the flow channel and result indeposition on the hot substrates.

However, a portion of the chemical reaction occurs sooner that desirableas the gas travels though the channel and a substantial portion,possibly most, of the reactants in the gas are consumed close to the gasinlet. A diminishing amount of the source gas is left as gas travelsalong the channel. This is known as depletion effect. The depletioneffect is well known and commonly occurs in horizontal reactors, wheregas travels from one end of the chamber horizontally to the other end ofthe chamber.

In the case of GaN growth, the reactants used can be trimethylgallium(TMG) and ammonia (NH₃), both of which can be carried by either hydrogen(H₂) or nitrogen (N₂). The supply of NH₃ is much greater than the supplyof TMG in a typical metalorganic chemical vapor deposition (MOCVD)growth process for GaN in order to prevent decomposition of GaN at thesurface. This is the case for III-V compounds and III-nitride growthusing MOCVD where group V gas supply is much greater than group III.Therefore the depletion effect that adversely affects growth uniformityis mostly due to the depletion of group III sources.

Referring now to FIG. 11, according to at least one aspect of thepresent invention, the group III and group V gas inlets are separated. Atop or lid 212 of a reactor 211 has an NH₃ inlet 213 formed generallycentrally therein. A plurality of group V injectors 214 are formed inthe lid in a manner that defines a plurality of zones (best seen in FIG.12)

Referring now to FIG. 12, a plurality of separate zones 250 are definedby separate groupings of group III invectors 214. Each grouping ofinjectors 214 is positioned within a dedicated one of the zones 250. Allof the injectors 214 of a given zone 250 can have common plumbing andthe flow for each zone is separately controllable with respect to theflow through the injectors 214 of the other zones 250. That is, theamount of gas flowing into each zone can be controlled by a dedicatedflow controller so that any desired group III gas (source) distributioncan be adjusted flexibly. Either the same gases or different gases canflow through the injectors of each grouping 214. Thus, the flow rate forall of the injectors 214 can be approximately the same and theconcentration of the group III reactants can be varied from zone tozone, for example.

Three zones 250 and consequently three groups of injectors 214 are shownin FIG. 12. However, those skilled in the art will appreciate that anydesired number of zones 250 and any desired number of groups ofinjectors 214 can be provided. Each zone 250 can contain any desirednumber of injectors 214. Indeed, every single injector can define a zoneand can be individually controlled with respect to what gases areinjected therewith and the flow rate of injection. Thus, theconfiguration of zones 250 and injectors 214 shown in FIGS. 11 and 12and discussed herein is by way of example only, and not by way oflimitation.

The lid 212 can comprise any desired number of injectors 214. Forexample, the lid 212 can comprises 12, 24, 36, 48, 64, or more injectors214. Further, each zone can contain any desired number of injectors 214.For example, each zone can contain 4, 6, 8, 12, or more injectors 214.

By keeping the group V gas inlet 213 at the center of the lid 212 anddistributing the group III gas in a controlled manner over the entirelid 212, laminar flow is established by the group V gas whileeliminating the depletion effect of group III source. Much betterdeposition uniformity over the entire wafer carrier can be achieved. Thewafer carrier can rotate at a rate of between approximately 10 rpm andapproximately 1500 rpm. The pressure in the reactor can be less than orequal to approximately 760 torr.

Distributing group III gas over the entire lid 212 can be achieved bycreating holes (injectors) in the lid. Water cooling of the group IIIinjectors can also provided to prevent premature decomposition of thegroup III sources.

It is understood that the exemplary method and apparatus for chemicalvapor deposition described herein and shown in the drawings representsonly presently preferred embodiments of the invention. Indeed, variousmodifications and additions may be made to such embodiments withoutdeparting from the spirit and scope of the invention. For example, itshould be appreciated that the apparatus and method of the presentinvention may find applications which are different from metal organicchemical vapor deposition. Indeed, the present invention may be suitablefor application completely unrelated to the fabrication of semiconductordevices.

Thus, these and other modifications and additions may be obvious tothose skilled in the art and may be implemented to adapt the presentinvention for use in a variety of different applications.

1. A chemical vapor deposition reactor system comprising: a plurality of chambers; a rotatable wafer carrier disposed within each of the chambers; and a common reactant gas supply configured to controllably provide substantially the same gas mixture to each chamber independently of each other.
 2. The chemical vapor deposition reactor system as recited in claim 1, further comprising a common gas exhaust system for the chambers.
 3. The chemical vapor deposition reactor system as recited in claim 1, further comprising gas flow controllers that facilitate control of an amount of gas provided to the chambers.
 4. The chemical vapor deposition reactor system as recited in claim 1, wherein gas is supplied to the chambers simultaneously.
 5. The chemical vapor deposition reactor system as recited in claim 3, wherein the amount of gas provided to the chambers is different for each chamber.
 6. The chemical vapor deposition reactor system as recited in claim 2, wherein each chamber further comprises a narrow flow channel formed intermediate the chamber and the wafer carrier, a gas inlet located at a top of the chamber, a gas exit above the wafer carrier, a sealing ring around the wafer carrier to facilitate flow laminarly to the exhaust system and to define a heater chamber.
 7. The chemical vapor deposition reactor system as recited in claim 1, wherein each chamber is a comparatively small chamber.
 8. The chemical vapor deposition reactor system as recited in claim 1, wherein each chamber defines a seven wafer reactor.
 9. A chemical vapor deposition reactor comprising: a chamber containing a rotatable wafer carrier; wherein generally laminar flow of gas is effected intermediate a portion of the chamber and the wafer carrier wherein the wafer carrier and the chamber cooperate to define a generally flat, continuous and unobstructed flow channel; a ring diffuser disposed proximate a periphery of the wafer carrier wherein laminar flow is enhanced from a reaction gas inlet formed generally centrally in the chamber to the ring diffuser; and a ring seal, wherein the ring seal is disposed around the rotatable wafer carrier to bridge the flow channel.
 10. The reactor as recited in claim 9, wherein the chamber is defined by a cylinder.
 11. The reactor as recited in claim 9, wherein the ring diffuser is comprised of at least one of SiC coated graphite, SiC quartz, or molybdenum.
 12. The reactor as recited in claim 9, wherein: a reaction gas inlet is formed generally centrally in the chamber; a plurality of reaction gas outlets are formed in the chamber; the wafer carrier is disposed within the chamber below the gas outlets so as to define a flow channel intermediate a top of the chamber and the wafer carrier such that reaction gas flows into the chamber through the reaction gas inlet, through the chamber via the flow channel, and out of the chamber via the reaction gas outlet; and the ring diffuser further comprises: a substantially hollow annulus having an inner surface and an outer surface; a plurality of openings formed in the inner surface; a plurality of openings formed in the outer surface; and wherein openings in the inner surface enhance uniformity of reaction gas flow over the wafer carrier.
 13. A chemical vapor deposition reactor comprising: a plurality of reactor chambers; a common gas supply adapted to provide reaction gases to the chambers; gas controllers individually controlling amounts of components of the reaction gases directly provided to each of the chambers independently from each other; and a common gas exhaust system for removing gases from the chambers.
 14. The reactor as recited in claim 13, further comprising supporting less than twelve wafers upon a wafer carrier disposed within each chamber.
 15. The reactor system as recited in claim 13, wherein each chamber further comprises a narrow flow channel formed intermediate the chamber and a wafer carrier, a gas inlet located at a top of the chamber, a gas exit above the wafer carrier, a sealing ring around the wafer carrier to facilitate flow laminarly to the exhaust system and to define a heater chamber.
 16. The reactor as recited in claim 15, wherein the ring seal further comprises at least one of graphite, quartz, and SiC. 